Capacitive Biosensor for Rapid Detection of Avian (H5N1) Influenza and E. coli in Aerosols

Joshin Kumar; Meng Xu; Yuezhi August Li; Shu Wen You; Brookelyn M. Doherty; Woodrow D. Gardiner; John R. Cirrito; Carla M. Yuede; Ananya Benegal; Michael D. Vahey; Astha Joshi; Kuljeet Seehra; Adrianus C.M. Boon; Yin Yuan Huang; Joseph V. Puthussery; Rajan K. Chakrabarty

doi:10.1021/acssensors.4c03087

Capacitive Biosensor for Rapid Detection of Avian (H5N1) Influenza and E. coli in Aerosols

Joshin Kumar, Meng Xu, Yuezhi August Li, Shu Wen You, Brookelyn M. Doherty, Woodrow D. Gardiner, John R. Cirrito, Carla M. Yuede, Ananya Benegal, Michael D. Vahey, Astha Joshi, Kuljeet Seehra, Adrianus C.M. Boon, Yin Yuan Huang, Joseph V. Puthussery, Rajan K. Chakrabarty

Research output: Contribution to journal › Article › peer-review

Abstract

Airborne transmission via aerosols is a dominant route for the transmission of respiratory pathogens, including avian H5N1 influenza A virus and E. coli bacteria. Rapid and direct detection of respiratory pathogen aerosols has been a long-standing technical challenge. Herein, we develop a novel label-free capacitive biosensor using an interlocked Prussian blue (PB)/graphene oxide (GO) network on a screen-printed carbon electrode (SPCE) for direct detection of avian H5N1 and E. coli. A single-step electro-co-deposition process grows GO branches on the SPCE surface, while the PB nanocrystals simultaneously decorate around the GO branches, resulting in an ultrasensitive capacitive response at nanofarad levels. We tested the biosensor for H5N1 concentrations from 2.0 viral RNA copies/mL to 1.6 × 10⁵ viral RNA copies/mL, with a limit of detection (LoD) of 56 viral RNA copies/mL. We tested it on E. coli for concentrations ranging from 2.0 bacterial cells/mL to 1.8 × 10⁴ bacterial cells/mL, with a LoD of 5 bacterial cells/mL. The detection times for both pathogens were under 5 min. When integrated with a custom-built wet cyclone bioaerosol sampler, our biosensor could detect and quasi-quantitatively estimate H5N1 and E. coli concentrations in air with spatial resolutions of 93 viral RNA copies/m³ and 8 bacterial cells/m³, respectively. The quasi-quantification method, based on dilution and binary detection (positive/negative), achieved an overall accuracy of >90% for pathogen-laden aerosol samples. This biosensor is adaptable for multiplexed detection of other respiratory pathogens, making it a versatile tool for real-time airborne pathogen monitoring and risk assessment.

Original language	English
Journal	ACS Sensors
DOIs	https://doi.org/10.1021/acssensors.4c03087
State	Accepted/In press - 2025

Keywords

E. coli
H5N1
Prussian blue
aerosol
capacitive biosensor
graphene oxide

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10.1021/acssensors.4c03087

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Kumar, J., Xu, M., Li, Y. A., You, S. W., Doherty, B. M., Gardiner, W. D., Cirrito, J. R., Yuede, C. M., Benegal, A., Vahey, M. D., Joshi, A., Seehra, K., Boon, A. C. M., Huang, Y. Y., Puthussery, J. V., & Chakrabarty, R. K. (Accepted/In press). Capacitive Biosensor for Rapid Detection of Avian (H5N1) Influenza and E. coli in Aerosols. ACS Sensors. https://doi.org/10.1021/acssensors.4c03087

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title = "Capacitive Biosensor for Rapid Detection of Avian (H5N1) Influenza and E. coli in Aerosols",

abstract = "Airborne transmission via aerosols is a dominant route for the transmission of respiratory pathogens, including avian H5N1 influenza A virus and E. coli bacteria. Rapid and direct detection of respiratory pathogen aerosols has been a long-standing technical challenge. Herein, we develop a novel label-free capacitive biosensor using an interlocked Prussian blue (PB)/graphene oxide (GO) network on a screen-printed carbon electrode (SPCE) for direct detection of avian H5N1 and E. coli. A single-step electro-co-deposition process grows GO branches on the SPCE surface, while the PB nanocrystals simultaneously decorate around the GO branches, resulting in an ultrasensitive capacitive response at nanofarad levels. We tested the biosensor for H5N1 concentrations from 2.0 viral RNA copies/mL to 1.6 × 105 viral RNA copies/mL, with a limit of detection (LoD) of 56 viral RNA copies/mL. We tested it on E. coli for concentrations ranging from 2.0 bacterial cells/mL to 1.8 × 104 bacterial cells/mL, with a LoD of 5 bacterial cells/mL. The detection times for both pathogens were under 5 min. When integrated with a custom-built wet cyclone bioaerosol sampler, our biosensor could detect and quasi-quantitatively estimate H5N1 and E. coli concentrations in air with spatial resolutions of 93 viral RNA copies/m3 and 8 bacterial cells/m3, respectively. The quasi-quantification method, based on dilution and binary detection (positive/negative), achieved an overall accuracy of >90% for pathogen-laden aerosol samples. This biosensor is adaptable for multiplexed detection of other respiratory pathogens, making it a versatile tool for real-time airborne pathogen monitoring and risk assessment.",

keywords = "E. coli, H5N1, Prussian blue, aerosol, capacitive biosensor, graphene oxide",

author = "Joshin Kumar and Meng Xu and Li, {Yuezhi August} and You, {Shu Wen} and Doherty, {Brookelyn M.} and Gardiner, {Woodrow D.} and Cirrito, {John R.} and Yuede, {Carla M.} and Ananya Benegal and Vahey, {Michael D.} and Astha Joshi and Kuljeet Seehra and Boon, {Adrianus C.M.} and Huang, {Yin Yuan} and Puthussery, {Joseph V.} and Chakrabarty, {Rajan K.}",

note = "Publisher Copyright: {\textcopyright} 2025 The Authors. Published by American Chemical Society.",

year = "2025",

doi = "10.1021/acssensors.4c03087",

language = "English",

journal = "ACS Sensors",

issn = "2379-3694",

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T1 - Capacitive Biosensor for Rapid Detection of Avian (H5N1) Influenza and E. coli in Aerosols

AU - Kumar, Joshin

AU - Xu, Meng

AU - Li, Yuezhi August

AU - You, Shu Wen

AU - Doherty, Brookelyn M.

AU - Gardiner, Woodrow D.

AU - Cirrito, John R.

AU - Yuede, Carla M.

AU - Benegal, Ananya

AU - Vahey, Michael D.

AU - Joshi, Astha

AU - Seehra, Kuljeet

AU - Boon, Adrianus C.M.

AU - Huang, Yin Yuan

AU - Puthussery, Joseph V.

AU - Chakrabarty, Rajan K.

PY - 2025

Y1 - 2025

N2 - Airborne transmission via aerosols is a dominant route for the transmission of respiratory pathogens, including avian H5N1 influenza A virus and E. coli bacteria. Rapid and direct detection of respiratory pathogen aerosols has been a long-standing technical challenge. Herein, we develop a novel label-free capacitive biosensor using an interlocked Prussian blue (PB)/graphene oxide (GO) network on a screen-printed carbon electrode (SPCE) for direct detection of avian H5N1 and E. coli. A single-step electro-co-deposition process grows GO branches on the SPCE surface, while the PB nanocrystals simultaneously decorate around the GO branches, resulting in an ultrasensitive capacitive response at nanofarad levels. We tested the biosensor for H5N1 concentrations from 2.0 viral RNA copies/mL to 1.6 × 105 viral RNA copies/mL, with a limit of detection (LoD) of 56 viral RNA copies/mL. We tested it on E. coli for concentrations ranging from 2.0 bacterial cells/mL to 1.8 × 104 bacterial cells/mL, with a LoD of 5 bacterial cells/mL. The detection times for both pathogens were under 5 min. When integrated with a custom-built wet cyclone bioaerosol sampler, our biosensor could detect and quasi-quantitatively estimate H5N1 and E. coli concentrations in air with spatial resolutions of 93 viral RNA copies/m3 and 8 bacterial cells/m3, respectively. The quasi-quantification method, based on dilution and binary detection (positive/negative), achieved an overall accuracy of >90% for pathogen-laden aerosol samples. This biosensor is adaptable for multiplexed detection of other respiratory pathogens, making it a versatile tool for real-time airborne pathogen monitoring and risk assessment.

AB - Airborne transmission via aerosols is a dominant route for the transmission of respiratory pathogens, including avian H5N1 influenza A virus and E. coli bacteria. Rapid and direct detection of respiratory pathogen aerosols has been a long-standing technical challenge. Herein, we develop a novel label-free capacitive biosensor using an interlocked Prussian blue (PB)/graphene oxide (GO) network on a screen-printed carbon electrode (SPCE) for direct detection of avian H5N1 and E. coli. A single-step electro-co-deposition process grows GO branches on the SPCE surface, while the PB nanocrystals simultaneously decorate around the GO branches, resulting in an ultrasensitive capacitive response at nanofarad levels. We tested the biosensor for H5N1 concentrations from 2.0 viral RNA copies/mL to 1.6 × 105 viral RNA copies/mL, with a limit of detection (LoD) of 56 viral RNA copies/mL. We tested it on E. coli for concentrations ranging from 2.0 bacterial cells/mL to 1.8 × 104 bacterial cells/mL, with a LoD of 5 bacterial cells/mL. The detection times for both pathogens were under 5 min. When integrated with a custom-built wet cyclone bioaerosol sampler, our biosensor could detect and quasi-quantitatively estimate H5N1 and E. coli concentrations in air with spatial resolutions of 93 viral RNA copies/m3 and 8 bacterial cells/m3, respectively. The quasi-quantification method, based on dilution and binary detection (positive/negative), achieved an overall accuracy of >90% for pathogen-laden aerosol samples. This biosensor is adaptable for multiplexed detection of other respiratory pathogens, making it a versatile tool for real-time airborne pathogen monitoring and risk assessment.

KW - E. coli

KW - H5N1

KW - Prussian blue

KW - aerosol

KW - capacitive biosensor

KW - graphene oxide

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DO - 10.1021/acssensors.4c03087

M3 - Article

C2 - 39982783

AN - SCOPUS:85219069994

SN - 2379-3694

JO - ACS Sensors

JF - ACS Sensors

ER -

Capacitive Biosensor for Rapid Detection of Avian (H5N1) Influenza and E. coli in Aerosols

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Keywords

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